US2676196A - Electrical transducing element - Google Patents

Description

April 5 R. s. MARSDEN, JR

ELECTRICAL TRANSDUCING ELEMENT Filed Feb. 2'7, 195:

' Sol/ARE LAW DETECTOR INVENTOR. .B.J:Ml'm.]1! HM q M1,

ATTORNEYS of potential throughout. "particles, for example, the ions produced by the Patented Apr. 20, 1954 UNITED STATES OFFICE ELECTRICAL TRANSDUCING ELEMENT Ross S. Marsden, Jr., Bartlesville, kla., assignor to Phillips Petroleum Company, a corporation of Delaware Application February 27, 1953, Serial No. 339,424

17 Claims.

reaction of a flame, impinge upon the surface of such an element the constant potential distribution is disrupted which results in small currents flowing in the element until all of the points therein are once again at the same potential. During the time current is flowing, either one of the attached electrodes exhibits a potential variation with respect to the other elec- 'trode which depends upon the magnitude of 220,113, filed April 9, 1951.

'It further has been discovered that certain ceramic refractory materials can be employed 'to advantage as the sensing element in such a flame detecting system. For the most part, these ceramic materials exhibit high electrical resistance and generally are considered non-conductors. However, when exposed to regions of high temperatures their resistance is lowered considerably, that is, they exhibit a negative coeificient of thermal resistivity. In order to provide a satisfactory flame sensing element, it is essential that the resistance of the element remain relatively high under the conditions of operation.

Unfortunately, those ceramics which exhibit such high resistivity at high operating temperatures require higher baking temperatures than the metallic electrodes to which they are attached can withstand without melting or excessive corrosion.

Some difficulty has thus been experienced in fabricating suitable ceramic detecting elements for use in the measurement of high temperature flames.

'ment at'a known temperature.

An improved temperature measurin system also has been developed recently which is based upon the principle that there exists within any electrical resistance element a random statistical movement of electrical charges. The statistical movement of electrical charges is referred to as thermal noise because minute voltage fluctuations measured across the end terminals of a resistanc element are proportional to the absolute temperature of the element. The relationship can be expressed mathematically by the Nyquist formula:

where E equals the mean-square voltage fluetuations'across the resistance element, M is the frequency handover which the voltage fluctuations are measured, k is Boltzmanns gas constant, Re Z is the real part of the complex impedance of the element, and T is the absolute temperature of the element. It is to be understood that such thermal noise voltages are of considerably less magnitude than the previously mentioned flame signal and apparentlyare in no way connected therewith, but rather are dependent upon temperature alone. By employing this. thermal noise relationship the temperature of a first given resistance element can be obtained by comparing the voltage fluctuations generated across the flrstelement with the voltage fluctuations generated across a second ele- A system'for measuring temperature in accordance with this principle is described in the copending applicationof D. R; deBoisblanc and R. S. Mars'den, Jr Serial No. 220,115, filed April 9, 1951. I

In operating this thermal noise thermometer satisfactory results have been obtained with detecting-elements havin resistances of approximately 1000 to 10,000 ohms. However, considerable difiiculty has been encountered in constructing resistance elements for use in such a thermal noise thermometer, particularly for use at temperatures above approximately 1400 C. Metallic resistances generally are not satisfactory at these high temperatures because metals capable of withstanding high temperatures are relatively good conductors which necessitates the elements being constructed ofvery small cross-section and relatively great length in order to afford the desired ohmic resistance, Many of these difliculties have been overcome, however, by construct- 1y, substantially the same problems are encountered in constructing such temperature sensing elements as previously mentioned in conjunction with the flame detectin elements.

In accordance with the present invention, it has been discovered that suitable electrical transducing elements for use in high temperature regions can be prepared 'by bonding metallic electrodes to a high baking ceramic material by the use of a second low baking ceramic. These low baking ceramic materials, while not affording the resistance desired for high temperature measurements, are valuable as a bonding material to attach the metallic electrodes to the high resistance ceramic. Accordingly, this invention is directed primarily toward providing improved electrical transducing elements for use in both flame detectors and thermal noise thermometers.

It is an object of the invention to provide electrical transducing elements capable of withstanding extremely high temperatures.

Another object is to' provide a method of constructing ceramic electrical transducing elements for use in regions of high temperature.

A further object is'to provide electrical transducing elements which are rugged in construc- 'tion, economical to manufacture, and which pos- "sess the desired electrical properties needed for satisfactory operation in regions 'of high temperature.

Various other objects, advantages, and features of this invention should becom apparent from the followin detailed description taken in conjunction with the accompanying drawing in which:

Figure l is a schematic view of flame detecting apparatus employinga'transducing element constructed in accordance with this invention as the sensing element;

Figure 2 is a schematic view of thermal noise temperature measurin apparatus employing a transducing element constructed'in accordance with this invention as the sensing element; and

Figures 3, 4, and 5 illustrate various forms of electrical transducin elements constructed in accordance with this invention.

Referring now to the drawing in detailand'to Figure 1 in particular, there is shown a ceramic transducing element ill which is disposed in the regionof a flame H, the presence of which is to be detected. One terminal of element an is grounded by a lead l2 and the second terminal thereof is connected by a lead 13 to one terminal of a condenser 14. The second terminal of condenser !4 is connected to one input terminal of an alternating current amplifier Hi, the second input terminal of which is grounded. The outcated on meter I! in a manner which is more fully described in the above mentioned application, Serial No. 220,113. I

In Figure 2 there is illustrated a simplified embodiment of the above mentioned thermal noise thermometer. A variable impedance element 20 and an electrical transducing element in are connected alternately in circuit with an amplifier 22, a square law detector 23, and a meter 24 by means of a switch 25. Resistance element 20 is maintained at a known reference temp rature -supports such as 32.

whereas element It) is positioned in the region of the unknown temperature being measured. In operating this thermometer the impedances of the two elements it and 20 first are equalized over a predetermined frequency range by suitable means, not shown. This equalization can be accomplished by applying an alternating voltage of variable frequency first across one element and then the other. The corresponding voltage drops across each element are measured and the impedance of element 28 is adjusted until the impedances of the two elements are equalized over a preselected frequency range. Thermal noise voltage fluctuations generated across each of the elements then are read on meter 24, which due to the presence of square law detector 23, are proportional to the mean-square voltage fluctuations generated across each element. The ratio of these readings is directly proportional to the ratio of temperatures of the elements; and, accordingly, the temperature of element l0 can readily be calculated.

The transducing elements illustrated in Figures 3, 4, and 5 are constructed in accordance withthe present invention for use as element ID in either ofthe-circuits illustrated in Figures 1 or 2.

Referring now to Figure 3, the electrical transducing element is shownas comprisinga cylindrically shaped metallic casing 30 having a metallic electrode 3| disposed axially therein and electrically insulated from casing 30 by insulating Casing 30 and electrode 3| are constructed of metals having high melting points, for example: platinum, tungsten, or iridium. A hollow cylindrical pre-fired high baking ceramic plug 33 is positioned within one end of casing 30. Electrode 3| extends through the center of plug 33 and is attached thereto by "a quantity of low baking ceramic material 34 which is molded about plug 33 and sintered. Plug 33 is likewise attached to casing 30 by a quantity of like ceramic material 34a which is molded about the end portion of casing 3c and plug 33. A plurality ofholes 35 are drilled near the end of casing 30 to facilitate attachment or material 34a to casing 30. Electrical leads l2 and liare secured to casing 30 and electrode 3|, respectively, to connect the transducing element in the electrical circuitry of either Figure l or Figure 2.

In Figure 4 there-is shown a modified form of the transducing element of Figure 3. In this embodiment casing 30 is replaced by a metalliccasing 40 and plug 33 is replaced by a flanged hollow ceramic plug 4|. The end 42 of easing 4-3 is bent "around'the flanged portion of plug 4| so as to form a'ri'gid connection therewith without the use of a binding material. Otherwise, the construction of the element shown in Figure 4 is 'ramic. Silicon carbide can be used to advantage in this respect. Gther ceramics which become relatively'good conductors include titanium car bide, zirconium carbide, columbium carbide, tantalum carbide, tungsten carbide, and hafnium carbide. Any of these materials can be employed to advantage in the construction of casing 43 and rod 44.

5 As employed herein, the phase baking temperature refers to the temperature to which the moulded ceramic materialsmust be heated to obtain appreciable strength. The phrases firing temperature and maturing temperature. are often employed in the art in like manner. The phrase low baking" is employed herein to desi inate baking temperatures below approximately 1000 C. and the phrase high baking is employed to designate baking temperatures above approximately 1400. C.

As an example of the constructionof the transducing element illustrated in Figure 3, casing. 30

. and electrode 3i are formed of tungsten Plug 33 .is formed of a ceramic comprising 99.3% by weight aluminum oxide and 0.7% silicon dioxide and having a baking temperature of approximately 1790 C. Bonding ceramics 34 and 34a are form-ed of the same material as. plug 33 to a which has been added sufficient clay to reduce the baking temperature of the resulting mixture to approximately 1000 C. This mixture is powdered and sufficient water is added to make a workable cement which is moulded about plug 34, casing 30, and electrode 3| as illustrated. The entire assembly is then heated to at least 1000" C. to bake ceramics 34 and 34a.

As a second example of the construction of the transducing element illustrated in Figure 3, casing 30 and electrode 3| are formed of platinum. Plug 33 is formed of a ceramic comprising 86.0%

. by weight aluminum oxide, 13.0% silicon dioxide,

and the remainder being mainly titanium dioxide, ferric oxide, and sodiumoxide, and having a baking temperature of approximately 1400 C.=

Bonding ceramics 34 and 34a are formed of the same material as plug 33 to which has been added suiiicient clay to reduce the baking temperature of the resulting mixture to approximately 700 C.

The actual mode of construction is the same as above mentioned.

In addition to the above examples, various other ceramics can be used in constructing the transducing elements'of this invention. The high baking ceramics for plugs 33 and I can be formed of any such materials which are capable of withstanding the high temperatures under consideration and which at the same time afford the desired ohmic resistance. Ceramics comprising generally from 86.0% to 99.5% by weight I aluminum oxide, 0.5 to 14.0% silicon carbide, the remainder, if any, being mainly titanium dioxide, ferric oxide and sodium oxide, having a specific gravity of from 3.8 to 4.2, and having a baking temperature above 1400 C. can be employed to advantage. Still another suitable ceramic comprises, for example, approximately 97.0% by weight magnesium oxide, 1.5% calcium oxide, and 1.5% silicon dioxide. The low baking bonding ceramics 34 and 34a can be prepared by adding sufiicient clay to any of the described high baking ceramics to reduce the baking temper--- 6 What is claimed .is':

1. An electrical transducing element comprising, in combination; a pair of opposing spaced wherein said pair of opposing spaced electrodes are constructed of metal having a melting temperature above 1000" C.

3. The combination in accordance with claim 1 wherein said pair of opposing spaced electrodes are constructed of electrically conductive ceramic material 4. The combination in accordance withclaim 3 wherein said opposing electrodes are constructed of electrically conductive ceramics selected from the group consisting of silicon carbide, titanium carbide, zirconium carbide, columbium carbide, tantalum carbide, tungsten carbide, and hafnium carbide. I

5. The combination in accordance with claim-l wherein said ceramic resistance element comprises from 86.0 to 99.5 per cent by weight aluminum oxide and 0.5 to 14.0 per cent silicon dioxide, the remainder being mainly titanium oxide, ferric oxide and sodium oxide, said element having a specific gravity of from 3.8 to 4.2; and said second-mentioned ceramic material comprises said first-mentioned ceramic material to which has been added sufficient clay to reduce the baking temperature thereof below 1000 C. 1 J I l 6. The combination in accordance with claim 5 wherein said ceramic resistance element comprises 86.0 per cent by weight alumnium oxide and 13.0 per cent silicon dioxide,-the remainder being mainly titanium dioxide, ferric oxide, and sodium oxide; and said second-mentioned 1 ccramic material comprises said first-mentioned ceramic material to which has been added sufficient clay to reduce the baking temperature thereof to approximately 700 C.

'7. The combination in accordance with claim 1 wherein said ceramic resistance element comprises 99.3 per cent by weight aluminum oxide and 0.7 per cent silicon dioxide and has a baking temperature of approximately 1790 C.; and said second-mentioned ceramic material comprises said first-mentioned ceramic material to which has been added suflicient clay to reduce the baking temperature thereof below 1000 C.

8. The combination in accordance with claim 1 wherein said ceramic resistance element comprises 97.0 per cent by weight magnesium oxide, 1.5 per cent calcium oxide and 1.5 per cent silicon dioxide; and said second-mentioned ceramic ma terial comprises said first-mentioned ceramic material to which has been added sufficient clay to reduce the baking temperature thereof below 1000" C.

9. An electrical transducing element, comprising, in combination, a hollow cylindrical metallic electrode, a second elongated electrode positioned within and electrically insulated from said first electrode, a hollow cylindrical ceramic resistance element positioned adjacent one end of said first electrode, one end of said second electrode extending through the hollow portion of said resistance element, and a. quantity of electrically conductive ceramic material securing said first 7 and second electrodes to said resistance element,

saidceramic resistance element having a baking temperature above 1400" C., and said secondmentioned ceramic material having a baking temperature below 1000 C.

10. The combination in accordance with claim 9 wherein said second electrode is constructed of a metal having a melting temperature above l000 C. and said first electrode has a melting temperature above 1000" C.

11. The combination in accordance withclaim 10 wherein said ceramic resistance element comprises from 86.0 to 99.5 per centby weight aluminum oxide and 0.5 to 'l4'.0 per cent-silicon dioxide, the remainder being mainly titanium oxide,.ferric oxide and sodium oxide-said elementhaving a specific gravity of from 3.8 to 4.2; and said second-mentioned ceramic material comprises said first-mentioned ceramic material to which has been added sufficient clay to reduce the baking temperature thereof below 1000 C.

12. An electrical transducing element comprising, in comibnation, a hollow-cylindrical metallic electrode, a second elongated electrode positioned within and' electrically insulated from said first electrode, a hollow cylindrical ceramic 'resistanceelement disposed within said first elec trode and secured to one end thereof, one end of saidsecond electrode extending-through the hollow portion of said resistance element, and a quantity of-electrically conductiveceramic material securing said second electrode to said resistance element, said ceramic resistance element having a baking temperature above 1400 C., and said second-mentioned ceramic material having a baking temperature below 1000 C.

13. The combination in accordance with claim 12 wherein said first and second elements are constructed of a material selected from the group consisting of silicon carbide, titanium carbide,

zirconium carbide, columbium carbide, tantalum carbide, tungsten carbide, and hafnium carbide.

14. The combination inaccordance with claim 13 wherein said ceramic resistance elementconv prisesfrom 86.0 to 99.5 ,per cent by weight aluminum oxide and 0.5 to.14.01per .centsilicon dioxide. the'remainder being mainly titanium oxide, ferric oxide and sodium oxide, said element having .a specific gravity of drum 3.8 to 4.2; and said second-mentioned ceramic material comprisesvsaid first-mentioned ceramic material to which has been added sufficient clay to reduce the baking temperature thereof below 1000-.C.

15. An electrical .transducing element comprising, in combination, a hollowcylindricalelectrode constructed of a conductive ceramic material, a second elongated electrode positioned within and electrically insulated from said first electrode, a hollow cylindrical ceramic resistance element positioned adjacent one end of said first electrode, one end of said second electrode extending through the hollow portion of saidresistance element, and a quantity of electrically conductive ceramic material securing said first and second electrodes to said resistance element, said ceramic resistance elementhaving a baking temperature above 1400 C., and said secondnientioned ceramic material having a baking temperature below 1000 C.

16. The combination in accordance with'claim 15 wherein said first andsecond elements are constructed of a material selected from the group consisting of silicon carbide, titanium carbide, zirconium carbide, columbium "carbide, tantalum carbide, tungsten carbide, and hafnium carbide.

l7.'The combinationinnccordance with claim 16 wherein said ceramic resistance element comprises from 86.0 to 99.5 per cent by weight'aluminum oxide, and 0:5 to 14.0 per centsilicon dioxide, the remainder being mainly titanium oxide, ferric oxide and sodium oxide, said element having a specific gravity of from 3.8-to 4.2; andsaid second-mentioned ceramic material comprises said first-mentioned ceramic material to which ,has been added suflicient clay to reduce .the baking temperature thereof below .1000 C.

No references cited.

Claims (1)

1. AN ELECTRICAL TRANSDUCING ELEMENT COMPRISING, IN COMBINATION, A PAIR OF OPPOSING SPACED ELECTRODES, AND A CERAMIC RESISTANCE ELEMENT DISPOSED BETWEEN SAID SPACED ELECTRODES, SAID ELEMENT BEING SECURED TO SAID ELECTRODES BY A QUAN-

Images